Y chromosome--specific DNA sequences in Turner-syndrome mosaicism.

Phenotypic females with Y-chromosomal material in their genome have an increased risk for development of gonadal malignancy. The detection and identification of Y-chromosomal material in these cases can be of critical importance for medical management. Chromosome analysis in four patients with Turner syndrome revealed the characteristic 45,X chromosome complement together with a second cell population containing a small marker chromosome (46,X, + mar). Molecular-hybridization analyses utilizing cloned, Y chromosome-specific DNA sequences were performed to determine whether Y-chromosomal material was present in each patient. Three cases contained some Y chromosome-specific sequences, whereas one case was negative with all four probes that we used. These results were compared with detailed cytogenetic studies--including G-, Q-, and G-11-banding--of the marker chromosomes. In one case in which Y chromosome-specific DNA sequences were demonstrated, the marker chromosome was G-11 negative. These results demonstrate that cytogenetic analysis alone can lead to misidentification of some Y chromosome-derived markers. The combination of cytogenetic and molecular analyses permits a more accurate characterization of anomalous Y chromosomes and in turn provides additional information that can be crucial to the correct medical management of Turner-syndrome patients.     

Identification of Y-chromosomal DNA in a Turner syndrome mosaic by polymerase chain reaction.

A 15.5-year-old female was referred for primary amenorrhea and slow development of secondary sex characteristics. The karyotype revealed 45,X/46,X,+mar (75%/25%). The small marker chromosome was C-band and Q-band negative. It appeared to be primarily centromeric with some light G-band staining material on either side. Females with Y-chromosomal material are at an increased risk for gonadal neoplasia and this patient was studied further to investigate the possibility that the marker was a deleted Y chromosome. Polymerase chain reaction (PCR) analysis of this patient's DNA revealed the presence of Y-chromosomal material presumably derived from the marker chromosome. These results indicate that the PCR technique, in conjunction with cytogenetic analysis, can identify possible Y-chromosomal material. This testing provides critical information necessary for correct medical followup of Turner syndrome mosaic patients.     

Delineation of marker chromosomes by reverse chromosome painting using only a small number of DOP-PCR amplified microdissected chromosomes

A new procedure for determining the chromosomal origin of marker chromosomes has been carried out. The origin of marker chromosomes that were unidentifiable by standard banding techniques could be verified by reverse chromosome painting. This technique includes microdissection, followed by in vitro DNA amplification and fluorescence in situ hybridization (FISH). A number of marker chromosomes prepared from unbanded and from GTG-banded lymphocyte chromosomes were collected with microneedles and transferred to a collection drop. The chromosomal material was amplified by a degenerate oligonucleotide-primed polymerase chain reaction (DOP-PCR). The resulting PCR products were labelled by nick-translation with biotin-11-dUTP and used as probes for FISH. They were hybridized onto normal metaphase spreads in order to determine the precise regional chromosomal origin of the markers. Following this approach, we tested 2–14 marker chromosomes in order to determine how many are necessary for reverse chromosome painting. As few as two marker chromosomes provided sufficient material to paint the appropriate chromosome of origin, regardless of whether the marker contained heterochromatic or mainly euchromatic material. With this method, it was possible to identify two marker chromosomes of a healthy proband [karyotype: 48,XY, +mar₁,+mar₂] and an aberrant Y chromosome of a mentally retarded boy [karyotype: 46,X, der(Y)].     

Molecular differentiation of the homomorphic sex chromosomes inMegaselia scalaris (Diptera) detected by random DNA probes

Randomly cloned DNA fragments and a poly-(GATA) containing sequence were used as probes to identify sex chromosomal inheritance and to detect differences at the molecular level between the homomorphic X and Y in the phorid fly,Megaselia scalaris. Restriction fragment length differences between males and females and between two laboratory stocks of different geographic origin were used to differentiate between sex chromosomal and autosomal origin of the respective fragments. Five random probes detected X and Y chromosomal DNA loci and two others recognized autosomal DNA loci. One random probe and the poly(GATA) probe hybridized with both sex chromosomal and autosomal restriction fragments. Most of the Y chromosomal restriction fragments were conserved in length between the two stocks while most of the X chromosomal and autosomal fragments showed length polymorphism. It was concluded, therefore, that the Y chromosome contains a conserved segment in which crossover is suppressed and restriction site differences have accumulated relative to the X. These chromosomes, therefore, conform to a theoretically expected early stage of sex chromosome evolution.     

Identification and characterization of normal length nonfluorescent Y chromosomes: cytogenetic analysis,Southern hybridization and non-isotopic in situ hybridization

Summary In two female patients with a 45,X/46,X,+mar karyotype the marker chromosomes were identified as normal length nonfluorescent Y chromosomes (nlY^nf) using non-isotopic in situ hybridization (NISH) complementary to routine cytogenetic analysis and Southern hybridization. The recognition of the nlY^nf as isodicentric in both patients illustrates and confirms the usefulness and importance of NISH in the identification and characterization of this and many other types of complex chromosome rearrangements.     

Y-190, a DNA probe for the sensitive detection of Y-derived marker chromosomes and mosaicism

Summary A DNA probe (Y-190) is described that specifically hybridizes with repeated DNA sequences in the short arm of the human Y chromosome. The suitability of Y-190 to detect Y-derived DNA is shown in two patients with a 45,X/46,X+marker earyotype and in a third patient previously described as having a 45,X karyotype.     

Human and mouse amelogenin gene loci are on the sex chromosomes

Enamel is the outermost covering of teeth and is the hardest tissue in the vertebrate body. The enamel matrix is composed of enamelin and amelogenin classes of protein. We have determined the chromosomal locations for the human and mouse amelogenin (AMEL) loci using Southern blot analyses of DNA from human, mouse, or somatic cell hybrids by hybridization to a characterized mouse amelogenin cDNA. We have determined that human AMEL sequences are located on the distal short arm of the X chromosome in the p22.1----p22.3 region and near the centromere on the Y chromosome, possibly at the proximal long arm (Yq11) region. These chromosomal assignments are consistent with the hypothesis that perturbation of the amelogenin gene is involved in X-linked types of amelogenesis imperfecta, as well as with the Y-chromosomal locations for genes that participate in regulating tooth size and shape. Unlike the locus in humans, the mouse AMEL locus appears to be assigned solely to the X chromosome. Finally, together with the data on other X and Y chromosome sequences, these data for AMEL mapping support the notion of a pericentric inversion occurring in the human Y chromosome during primate evolution.     

Ring Y chromosome: molecular characterization by DNA probes

A young male with a karyotype of 46,X,+ mar is described. Physical mapping of the marker chromosome by using Y-specific single-copy or moderately repeated DNA sequences as molecular probes showed that, in addition to the heterochromatic part of the Yq, a considerable portion of the euchromatin in both Yp and Yq had been lost. These findings suggest that the marker chromosome is a ring Y, for the generally accepted model of ring formation implies breakages in both chromosome arms. The clinical features of the patient correlated well with the phenotypic changes expected from the loss of genetic material from the Y.     

FISH and PCR analyses in three patients with 45,X/46,X,idic(Y) karyotype: clinical and pathologic spectrum

OBJECTIVE: To delineate the phenotypic spectrum (clinical and gonadal features) from patients with a 45,X/46,X,mar(Y) karyotype based upon of their clinical, histological, cytogenetic and molecular evaluation. SUBJECTS: Three patients with a 45,X/46,X,mar(Y) karyotype. METHODS: Clinical assessment, karyotyping, endocrine evaluation, FISH and PCR analyses of several Y-chromosome loci and direct sequencing of the SRY gene. RESULTS: The patients, two males and one female had varying degrees of impairment of sexual differentiation, with or without testis formation. One patient (reared as female and aged 17 years) had Turner syndrome with bilateral streak gonads. The second patient (2.4 years old) had ambiguous genitalia and presented a dysgenetic testis with a contralateral streak gonad. A third patient (26 years old) had bilateral dysgenetic testes (dysgenetic male pseudohermaphroditism). The ratio of 45,X vs. 46,X,+mar(Y) cells differed between patients and between different tissues. In each case the marker sexual chromosome was identified as a rearranged Y-chromosome (idic(Y)) using FISH and PCR analyses. In all cases the SRY gene was present in all tissues studied. No mutations were identified in this gene in any of the patients. CONCLUSIONS: The extent of male or female differentiation in these patients depends in part on the prevalence, time occurrence, and distribution of the 45,X cell line.     

Heteromorphic X chromosomes in 46,XX males: Evidence for the involvement of X-Y interchange

Summary G- and R-banded chromosome preparations from eight of twelve 46,XX males, with no evidence of mosaicism or a free Y chromosome, were distinguished in blind trials from preparations from normal 46,XX females by virtue of heteromorphism of the short arm of one X chromosome. Photographic measurements on X chromosomes and on chromosome pair 7 in cells from twelve 46,XX males, eight 46,XX females, and four 46,XY males revealed a significant increase in the size of the p arm of one X chromosome in the group of XX males, independently characterised as being heteromorphic for Xp. No such differences were observed between X chromosomes of normal males and females or between homologues of chromosome pair 7 in all groups. The heteromorphism in XX males is a consequence of an alteration in shape (banding profile) and length of the tip of the short arm of one X chromosome, and the difference in size of the two Xp arms in these 46,XXp+ males ranged from 0.4% to 22.9%. From various considerations, including the demonstration of a Y-specific DNA fragment in DNA digests from nuclei of one of three XX males tested, it is concluded that the Xp+ chromosome is a product of Xp-Yp exchange. These exchanges are assumed to originate at meiosis in the male parent and may involve an exchange of different amounts of material. The consequences of such unequal exchange are considered in terms of the inheritance of genes located on Yp and distal Xp. No obvious phenotypic difference was associated with the presence or absence of Xp+. Thus, some males diagnosed as 46,XX are mosaic for a cryptic Y-containing cell line, and there is now excellent evidence that maleness in others may be a consequence of an autosomal recessive gene. The present data imply that in around 70% of 46,XX males, maleness is a consequence of the inheritance of a paternal X-Y interchange product.     

Molecular analysis of aberrations of Xp and Yq

Summary Three cases of Y chromosomal aberrations were studied using a panel of Y-specific DNA sequences from both Yp and euchromatic Yq. One case was a phenotypic male fetus with a Y-derived marker chromosome. The short arm of this chromosome was intact, but most of its long arm was missing. The second case had a 46,Xyq- karyotype with portions of euchromatic Yq, including the spermatogenesis region, missing. The third case was a phenotypic female with a 46,XXp+ karyotype. The extra material on the Xp+ chromosome was derived from the heterochromatic, and part of the euchromatic, portion of Yq. Application of X-specific DNA sequences demonstrated that the distal portion of the short arm of the translocation X chromosome was deleted (Xpter—p22.3). The three examples demonstrate the importance of diagnostic DNA analysis in cases of marker chromosomes, and X and Y chromosomal aberrations. In addition, the findings in the patients facilitate further deletion mapping of euchromatic Yq.     

Quantitative analysis of sex-chromosome mosaicism with X-Y DNA probes.

Sex-chromosome mosaicism was quantitatively analyzed in two patients using DNA probes specific for human X and Y chromosomes. Both patients were female with stigmata of the Turner syndrome, and both had a 45,X cell line and a 46,XY cell line. One of the patients had a morphologically abnormal, nonfluorescent Y chromosome, dic(Y)(q11). Hybridization of DNA from this patient with two repetitive DNA sequences specific for the heterochromatic region of the Y chromosome indicated that most of the Y-heterochromatic sequences were deleted. DNA from both patients was hybridized with a probe for the DXYS1 locus and found to have the X- and Y-linked loci. Densitometric measurements of the relative intensities of the X- and Y-linked bands were used to calculate the degree of mosaicism in each case. The percentages of 45,X cells obtained by DNA analysis agreed with those obtained by chromosome analysis. DNA analysis provides a way to quantitate mosaicism at the DNA level and in nondividing tissue.     

Characterization of a low copy repetitive element S232 involved in the generation of frequent deletions of the distal short arm of the human X chromosome.

There are several copies of related sequences on the distal short arm of the human X chromosome and the proximal long arm of the Y chromosome which were originally detected by cross hybridization with a genomic DNA clone, CRI-S232. Recombination between two S232-like sequences flanking the steroid sulfatase locus has been shown to cause frequent deletions in the X chromosome short arm, resulting in steroid sulfatase deficiency. We now report the characterization of several S232-like sequences. Restriction mapping and sequence analysis show that each S232 unit contains 5 kb of unique sequence in addition to two elements, RU1 and RU2, composed of a variable number of tandem repeats. RU1 consists of 30 bp repeating units and its length shows minimal variation between individuals. The RU2 elements in the hypervariable S232 loci on the X chromosome consist of repeating sequences which are highly asymmetric, with about 90% purines and no C's on one strand. The X-derived RU2 elements range from 0.6 kb to over 23 kb among different individuals, accounting entirely for the observed polymorphism at the S232 loci. Although the repeating units of the RU2 elements in the nonpolymorphic S232 loci on the Y chromosome share high sequence homology with those on the X chromosome, they exhibit much higher intrarepeat sequence variation. S232 homologous sequences are found in great apes, old world and new world monkeys. In chimpanzees and gorillas the S232-like sequences are polymorphic in length.     

Construction, analysis, and application to 46,XY gonadal dysgenesis of a recombinant phage DNA library from flow-sorted human Y chromosomes

The analysis of a recombinant human Y-enriched Hind III total digest phage library prepared from the DNA of flow sorted human Y chromosomes is described. Out of 43 phage inserts from the library thus far mapped, 25 revealed hybridization with Y chromosomal DNA. These inserts may be divided into five groups according to their degree of Y specific hybridization: inserts that hybridize with one single copy or slightly repeated Y-specific DNA sequence, Y-specific repeated sequences of various restriction fragment lengths, Y-chromosomal DNA sequence(s) shared by a sequence on the X and/or on autosomes, Y-specific DNA sequences in addition to multiple X and/or autosomal sequences, or Y-specific repeated DNA in addition to multiple X and/or autosomal sequences. Application of probes from this library for diagnostic purposes is shown in two 46,XY patients with gonadal dysgenesis and small deletions of the Y short arm.     

H-Y antigen expression in a case of mixed gonadal dysgenesis

Summary H-Y antigen expression was studied on leukocytes and gonad-derived fibroblasts from a patient affected by mixed gonadal dysgenesis. Blood leukocytes and fibroblasts derived from the testis were typed H-Y positive, but the fibroblasts derived from the streak gonad were H-Y negative. Although the patient's karyotype was a mosaic, 45,XO/46,X+mar, as detected in-peripheral blood cells and testis-derived fibroblasts, all the fibroblasts derived from the streak gonad were 45,XO. These data suggests that the marker chromosome was in fact a Y-derived chromosome. Moreover, they showed that, at the gonadal level, a minority of H-Y positive 46,X+mar cells were able to organize a testis. Nevertheless, a large number of XO cells probably did not receive the testicular forming influence of the H-Y antigen and of the other masculinizing factors.     

An unusual dicentric Y chromosome with a functional centromere with no detectable alpha-satellite

We describe an unusual marker chromosome Y. This marker is present in 5% of the lymphocytes of a dysgenetic woman showing a mosaic karyotype 45,X/46,XY/ 47,XY+mar. Q-banding revealed that the marker was morphologically identical to the Y chromosome of the patient but presented the primary constriction in the heterochromatic region. C-banding confirmed that the heterochromatic region was C-positive; furthermore, it showed two spots in the euchromatic region in a position corresponding to that of the centromere in the normal Y Fluorescence in situ hybridization with the centromere-specific probe pDP 97 and the pancentromeric alpha-satellite probe 2730 failed to detect any signal at the primary constriction site. To improve the characterization of the marker chromosome, hybridization was performed using pDP 105, a probe located on the short arm of the Y chromosome, together with chromosome-Y- specific paint-hybridizing to the single sequence spanning the Y short arm. In both cases, positive signals telomeric to the inactive centromere were observed. Possible mechanisms resulting in the formation of the marker chromosome are discussed.     

Hairy cell leukemia: an analysis of the chromosomes of 26 patients.

We studied the chromosomes from 26 patients with hairy cell leukemia (HCL) to ascertain the frequency and types of consistent chromosomal abnormalities. Samples from 21 patients were obtained from peripheral blood cultures grown 24 and 48 h without phytohemagglutinin, or from bone marrow samples. Two male patients had similar, consistent abnormalities; one patient's karyotype was 46, X, +12; that of the second was 46, X, +C marker. In the latter case, the distal long arm of the C marker most closely resembled chromosome No. 12 from band q14 to q terminal, but the short arm and proximal long arm were of undetermined origin. Both karyotypes lacked the Y chromosome. Nine of the 21 patients had abnormalities in single cells. One patient had, in one sample, a single abnormal cell with an extra No. 3 and an extra No. 12 (48, XY, +3, +12), and in a later sample, a second cell of poor morphology which also could have been trisomic for No. 12. Another patient had one cell with an unusually bright short arm, as well as two cells, with different abnormalities, both involving the short arm of chromosome No. 1. The two patients with consistent chromosome abnormalities had rapidly progressive disease in spite of splenectomy, and their clinical course from the time of diagnosis was relatively short (5 and 7 months, respectively).     

A chromosome study of 6-thioguanine-resistant mutants in T lymphocytes of Hiroshima atomic bomb survivors

Cytogenetic characterizations were made of lymphocyte colonies established from somatic mutation assays for 6-thioguanine (TG) resistance in Hiroshima atomic bomb survivors. G-banded chromosomes were analyzed in both TG-resistant (TGr) and wild-type colonies. Included were 45 TGr and 19 wild-type colonies derived from proximally exposed A-bomb survivors, as well as colonies from distally exposed control individuals who did not receive a significant amount of A-bomb radiation (18 TGr and 9-wild type colonies). Various structural and numerical chromosome abnormalities were observed in both TGr and wild-type colonies. Aberrations of the X chromosome, on which the hypoxanthine guanine phosphoribosyl transferase (HPRT) locus is present, were found in 6 colonies: 2 resistant colonies from controls (45,X/46,XX; 46,X,ins(X)), 3 resistant colonies (45,X/46,XX/46,X, + mar; 46,X,t(Xq +;14q-); 46,Y,t(Xq-;5q +)), and 1 wild-type colony (45,X/47,XXX) from proximally exposed persons. In cases with exchange aberrations, each of the break points on the X chromosome was situated proximally to band q26 where the HPRT locus is known to be assigned. DNA-replicating patterns were also studied, and it was found that abnormal X chromosomes showed early replicating patterns, while normal X chromosomes showed late replicating patterns.     

Mosaic down syndrome with a marker: molecular cytogenetic characterization of the marker chromosome

Down syndrome is a complex disorder characterized by well defined and distinctive phenotypic features. Approximately 2-3% of all live-born Down individuals are mosaics. Here we report a boy with suspected Down syndrome showing mosaicism for two different cell lines where one cell line is unexpected. The cytogenetic analysis by G-banding revealed a karyotype of 47 XY+21 [20]/46,X+marker [30]. Further, molecular cytogenetic analysis with spectral karyotyping identified the marker as a derivative of Y chromosome. The delineation of Y chromosomal DNA was done by quantitative real-time PCR and aneuploidy detection by quantitative fluorescence PCR. The Y-short tandem repeats typing was performed to estimate the variation in quantity as well as to find out the extent of deletion on Y chromosome using STR markers. Fluorescence in situ hybridization using Y centromeric probe was also performed to confirm the origin of the Y marker. Further fine mapping of the marker was carried out with three bacterial artificial chromosome clones RP11-20H21, RP11-375P13, RP11-71M14, which defined the hypothetical position of the deletion. In our study we defined the extent of deletion of the marker chromosome and also discussed it in relation with mosaicism. This is the first report of mosaic Down syndrome combined with a second de novo mosaic marker derived from the Y chromosome.     

Identification of the short arm of the Y chromosome by cytogenetic and molecular analyses

Isochromosome Y is one of the structural anomalies of the Y chromosome associated with a 45,X cell line and a broad spectrum of phenotypes. We present a case of de novo 46,X,+mar detected in a 17-yearold male patient. He had shortening of the right leg, bilateral breast enlargement, pubic, underarm and facial hair development, small penis and testicles, low serum cortisol, ACTH and total testosterone levels, normal LH value, high FSH value, normal testicles and epididymis, minimal left varicocele. The chromosome aberration was detected by cytogenetic analysis. Cytogenetic and molecular analysis was performed by conventional karyotyping and quantitative florescence PCR, respectively. The molecular analyses by PCR detected the presence of the SRY and AMXY genes, confirming the presence of the short arm of the Y chromosome. PCR demonstrated that the marker chromosome is of Y origin and corresponds to an authentic isochromosome for the short arm of the Y chromosome, i(Yp). We suggest that the structural alteration of the Y chromosome was a new mutation, which occurred in the initial mitotic division of the embryo, originally 46,XY. The result of accurate evaluation provides correct sex assignment and the prevention of the neoplastic degeneration of a dysgenetic gonad. The karyotype 46,X,i(Yp) indicates that the patient is preserving the SRY gene.